Same base. Rules for multiplying powers with different bases
It is obvious that numbers with powers can be added like other quantities , by adding them one after another with their signs.
So, the sum of a 3 and b 2 is a 3 + b 2.
The sum of a 3 - b n and h 5 -d 4 is a 3 - b n + h 5 - d 4.
Odds equal powers of identical variables can be added or subtracted.
So, the sum of 2a 2 and 3a 2 is equal to 5a 2.
It is also obvious that if you take two squares a, or three squares a, or five squares a.
But degrees various variables And various degrees identical variables, must be composed by adding them with their signs.
So, the sum of a 2 and a 3 is the sum of a 2 + a 3.
It is obvious that the square of a, and the cube of a, is not equal to twice the square of a, but to twice the cube of a.
The sum of a 3 b n and 3a 5 b 6 is a 3 b n + 3a 5 b 6.
Subtraction powers are carried out in the same way as addition, except that the signs of the subtrahends must be changed accordingly.
Or:
2a 4 - (-6a 4) = 8a 4
3h 2 b 6 - 4h 2 b 6 = -h 2 b 6
5(a - h) 6 - 2(a - h) 6 = 3(a - h) 6
Multiplying powers
Numbers with powers can be multiplied, like other quantities, by writing them one after the other, with or without a multiplication sign between them.
Thus, the result of multiplying a 3 by b 2 is a 3 b 2 or aaabb.
Or:
x -3 ⋅ a m = a m x -3
3a 6 y 2 ⋅ (-2x) = -6a 6 xy 2
a 2 b 3 y 2 ⋅ a 3 b 2 y = a 2 b 3 y 2 a 3 b 2 y
The result in the last example can be ordered by adding identical variables.
The expression will take the form: a 5 b 5 y 3.
By comparing several numbers (variables) with powers, we can see that if any two of them are multiplied, then the result is a number (variable) with a power equal to amount degrees of terms.
So, a 2 .a 3 = aa.aaa = aaaaa = a 5 .
Here 5 is the power of the result of the multiplication, equal to 2 + 3, the sum of the powers of the terms.
So, a n .a m = a m+n .
For a n , a is taken as a factor as many times as the power of n;
And a m is taken as a factor as many times as the degree m is equal to;
That's why, powers with the same bases can be multiplied by adding the exponents of the powers.
So, a 2 .a 6 = a 2+6 = a 8 . And x 3 .x 2 .x = x 3+2+1 = x 6 .
Or:
4a n ⋅ 2a n = 8a 2n
b 2 y 3 ⋅ b 4 y = b 6 y 4
(b + h - y) n ⋅ (b + h - y) = (b + h - y) n+1
Multiply (x 3 + x 2 y + xy 2 + y 3) ⋅ (x - y).
Answer: x 4 - y 4.
Multiply (x 3 + x - 5) ⋅ (2x 3 + x + 1).
This rule is also true for numbers whose exponents are negative.
1. So, a -2 .a -3 = a -5 . This can be written as (1/aa).(1/aaa) = 1/aaaaa.
2. y -n .y -m = y -n-m .
3. a -n .a m = a m-n .
If a + b are multiplied by a - b, the result will be a 2 - b 2: that is
The result of multiplying the sum or difference of two numbers is equal to the sum or difference of their squares.
If you multiply the sum and difference of two numbers raised to square, the result will be equal to the sum or difference of these numbers in fourth degrees.
So, (a - y).(a + y) = a 2 - y 2.
(a 2 - y 2)⋅(a 2 + y 2) = a 4 - y 4.
(a 4 - y 4)⋅(a 4 + y 4) = a 8 - y 8.
Division of degrees
Numbers with powers can be divided like other numbers, by subtracting from the dividend, or by placing them in fraction form.
Thus, a 3 b 2 divided by b 2 is equal to a 3.
Or:
$\frac(9a^3y^4)(-3a^3) = -3y^4$
$\frac(a^2b + 3a^2)(a^2) = \frac(a^2(b+3))(a^2) = b + 3$
$\frac(d\cdot (a - h + y)^3)((a - h + y)^3) = d$
Writing a 5 divided by a 3 looks like $\frac(a^5)(a^3)$. But this is equal to a 2 . In a series of numbers
a +4 , a +3 , a +2 , a +1 , a 0 , a -1 , a -2 , a -3 , a -4 .
any number can be divided by another, and the exponent will be equal to difference indicators of divisible numbers.
When dividing degrees with the same base, their exponents are subtracted..
So, y 3:y 2 = y 3-2 = y 1. That is, $\frac(yyy)(yy) = y$.
And a n+1:a = a n+1-1 = a n . That is, $\frac(aa^n)(a) = a^n$.
Or:
y 2m: y m = y m
8a n+m: 4a m = 2a n
12(b + y) n: 3(b + y) 3 = 4(b +y) n-3
The rule is also true for numbers with negative values of degrees.
The result of dividing a -5 by a -3 is a -2.
Also, $\frac(1)(aaaaa) : \frac(1)(aaa) = \frac(1)(aaaaa).\frac(aaa)(1) = \frac(aaa)(aaaaa) = \frac (1)(aa)$.
h 2:h -1 = h 2+1 = h 3 or $h^2:\frac(1)(h) = h^2.\frac(h)(1) = h^3$
It is necessary to master multiplication and division of powers very well, since such operations are very widely used in algebra.
Examples of solving examples with fractions containing numbers with powers
1. Reduce the exponents by $\frac(5a^4)(3a^2)$ Answer: $\frac(5a^2)(3)$.
2. Decrease the exponents by $\frac(6x^6)(3x^5)$. Answer: $\frac(2x)(1)$ or 2x.
3. Reduce the exponents a 2 /a 3 and a -3 /a -4 and bring to a common denominator.
a 2 .a -4 is a -2 the first numerator.
a 3 .a -3 is a 0 = 1, the second numerator.
a 3 .a -4 is a -1 , the common numerator.
After simplification: a -2 /a -1 and 1/a -1 .
4. Reduce the exponents 2a 4 /5a 3 and 2 /a 4 and bring to a common denominator.
Answer: 2a 3 /5a 7 and 5a 5 /5a 7 or 2a 3 /5a 2 and 5/5a 2.
5. Multiply (a 3 + b)/b 4 by (a - b)/3.
6. Multiply (a 5 + 1)/x 2 by (b 2 - 1)/(x + a).
7. Multiply b 4 /a -2 by h -3 /x and a n /y -3 .
8. Divide a 4 /y 3 by a 3 /y 2 . Answer: a/y.
9. Divide (h 3 - 1)/d 4 by (d n + 1)/h.
In the last video lesson, we learned that the degree of a certain base is an expression that represents the product of the base by itself, taken in an amount equal to the exponent. Let us now study some of the most important properties and operations of powers.
For example, let's multiply two different degrees with the same base:
Let's present this work in its entirety:
(2) 3 * (2) 2 = (2)*(2)*(2)*(2)*(2) = 32
Having calculated the value of this expression, we get the number 32. On the other hand, as can be seen from the same example, 32 can be represented as the product of the same base (two), taken 5 times. And indeed, if you count it, then:
Thus, we can confidently conclude that:
(2) 3 * (2) 2 = (2) 5
This rule works successfully for any indicators and any reasons. This property of power multiplication follows from the rule that the meaning of expressions is preserved during transformations in a product. For any base a, the product of two expressions (a)x and (a)y is equal to a(x + y). In other words, when any expressions with the same base are produced, the resulting monomial has a total degree formed by adding the degrees of the first and second expressions.
The presented rule also works great when multiplying several expressions. The main condition is that everyone has the same bases. For example:
(2) 1 * (2) 3 * (2) 4 = (2) 8
It is impossible to add degrees, and indeed to carry out any power-based joint actions with two elements of an expression if their bases are different.
As our video shows, due to the similarity of the processes of multiplication and division, the rules for adding powers in a product are perfectly transferred to the division procedure. Consider this example:
Let us carry out a term-by-term transformation of the expression into full view and reduce the same elements in the dividend and divisor:
(2)*(2)*(2)*(2)*(2)*(2) / (2)*(2)*(2)*(2) = (2)(2) = (2) 2 = 4
The end result of this example is not so interesting, because already in the process of solving it it is clear that the value of the expression is equal to the square of two. And it is two that is obtained by subtracting the degree of the second expression from the degree of the first.
To determine the degree of the quotient, it is necessary to subtract the degree of the divisor from the degree of the dividend. The rule works with the same basis for all its values and for all natural powers. In the form of abstraction we have:
(a) x / (a) y = (a) x - y
From the rule of dividing identical bases with degrees, the definition for the zero degree follows. Obviously, the following expression looks like:
(a) x / (a) x = (a) (x - x) = (a) 0
On the other hand, if we do the division in a more visual way, we get:
(a) 2 / (a) 2 = (a) (a) / (a) (a) = 1
When reducing all visible elements of a fraction, the expression 1/1 is always obtained, that is, one. Therefore, it is generally accepted that any base raised to the zero power is equal to one:
Regardless of the value of a.
However, it would be absurd if 0 (which still gives 0 for any multiplication) is somehow equal to one, so an expression of the form (0) 0 (zero to the zero power) simply does not make sense, and to formula (a) 0 = 1 add a condition: “if a is not equal to 0.”
Let's solve the exercise. Let's find the value of the expression:
(34) 7 * (34) 4 / (34) 11
Since the base is the same everywhere and equal to 34, the final value will have the same base with a degree (according to the above rules):
In other words:
(34) 7 * (34) 4 / (34) 11 = (34) 0 = 1
Answer: the expression is equal to one.
If you need to raise a specific number to a power, you can use . Now we will take a closer look at properties of degrees.
Exponential numbers open great opportunities, they allow us to convert multiplication into addition, and adding is much easier than multiplying.
For example, we need to multiply 16 by 64. The product of multiplying these two numbers is 1024. But 16 is 4x4, and 64 is 4x4x4. That is, 16 by 64 = 4x4x4x4x4, which is also equal to 1024.
The number 16 can also be represented as 2x2x2x2, and 64 as 2x2x2x2x2x2, and if we multiply, we again get 1024.
Now let's use the rule. 16=4 2, or 2 4, 64=4 3, or 2 6, at the same time 1024=6 4 =4 5, or 2 10.
Therefore, our problem can be written differently: 4 2 x4 3 =4 5 or 2 4 x2 6 =2 10, and each time we get 1024.
We can solve a series similar examples and we will see that multiplying numbers with powers reduces to adding exponents, or exponential, of course, provided that the bases of the factors are equal.
Thus, without performing multiplication, we can immediately say that 2 4 x2 2 x2 14 = 2 20.
This rule is also true when dividing numbers with powers, but in this case the exponent of the divisor is subtracted from the exponent of the dividend. Thus, 2 5:2 3 =2 2, which in ordinary numbers is equal to 32:8 = 4, that is, 2 2. Let's summarize:
a m x a n =a m+n, a m: a n =a m-n, where m and n are integers.
At first glance it may seem that this is multiplying and dividing numbers with powers not very convenient, because first you need to represent the number in exponential form. It is not difficult to represent the numbers 8 and 16, that is, 2 3 and 2 4, in this form, but how to do this with the numbers 7 and 17? Or what to do in cases where a number can be represented in exponential form, but the bases for exponential expressions of numbers are very different. For example, 8x9 is 2 3 x 3 2, in which case we cannot sum the exponents. Neither 2 5 nor 3 5 are the answer, nor does the answer lie in the interval between these two numbers.
Then is it worth bothering with this method at all? Definitely worth it. It provides enormous benefits, especially for complex and time-consuming calculations.
First level
Degree and its properties. Comprehensive guide (2019)
Why are degrees needed? Where will you need them? Why should you take the time to study them?
To learn everything about degrees, what they are for, how to use your knowledge in Everyday life read this article.
And, of course, knowledge of degrees will bring you closer to success passing the OGE or the Unified State Exam and admission to the university of your dreams.
Let's go... (Let's go!)
Important note! If you see gobbledygook instead of formulas, clear your cache. To do this, press CTRL+F5 (on Windows) or Cmd+R (on Mac).
FIRST LEVEL
Exponentiation is a mathematical operation just like addition, subtraction, multiplication or division.
Now I'll explain everything human language very simple examples. Be careful. The examples are elementary, but explain important things.
Let's start with addition.
There is nothing to explain here. You already know everything: there are eight of us. Everyone has two bottles of cola. How much cola is there? That's right - 16 bottles.
Now multiplication.
The same example with cola can be written differently: . Mathematicians are cunning and lazy people. They first notice some patterns, and then figure out a way to “count” them faster. In our case, they noticed that each of the eight people had the same number of cola bottles and came up with a technique called multiplication. Agree, it is considered easier and faster than.
So, to count faster, easier and without errors, you just need to remember multiplication table. Of course, you can do everything slower, more difficult and with mistakes! But…
Here is the multiplication table. Repeat.
And another, more beautiful one:
What other clever counting tricks have lazy mathematicians come up with? Right - raising a number to a power.
Raising a number to a power
If you need to multiply a number by itself five times, then mathematicians say that you need to raise that number to the fifth power. For example, . Mathematicians remember that two to the fifth power is... And they solve such problems in their heads - faster, easier and without mistakes.
All you need to do is remember what is highlighted in color in the table of powers of numbers. Believe me, this will make your life a lot easier.
By the way, why is it called the second degree? square numbers, and the third - cube? What does it mean? Very good question. Now you will have both squares and cubes.
Real life example #1
Let's start with the square or the second power of the number.
Imagine a square pool measuring one meter by one meter. The pool is at your dacha. It's hot and I really want to swim. But... the pool has no bottom! You need to cover the bottom of the pool with tiles. How many tiles do you need? In order to determine this, you need to know the bottom area of the pool.
You can simply calculate by pointing your finger that the bottom of the pool consists of meter by meter cubes. If you have tiles one meter by one meter, you will need pieces. It's easy... But where have you seen such tiles? The tile will most likely be cm by cm. And then you will be tortured by “counting with your finger.” Then you have to multiply. So, on one side of the bottom of the pool we will fit tiles (pieces) and on the other, too, tiles. Multiply by and you get tiles ().
Did you notice that to determine the area of the pool bottom we multiplied the same number by itself? What does it mean? Since we are multiplying the same number, we can use the “exponentiation” technique. (Of course, when you have only two numbers, you still need to multiply them or raise them to a power. But if you have a lot of them, then raising them to a power is much easier and there are also fewer errors in calculations. For the Unified State Exam, this is very important).
So, thirty to the second power will be (). Or we can say that thirty squared will be. In other words, the second power of a number can always be represented as a square. And vice versa, if you see a square, it is ALWAYS the second power of some number. A square is an image of the second power of a number.
Real life example #2
Here's a task for you: count how many squares there are on the chessboard using the square of the number... On one side of the cells and on the other too. To calculate their number, you need to multiply eight by eight or... if you notice that a chessboard is a square with a side, then you can square eight. You will get cells. () So?
Real life example #3
Now the cube or the third power of a number. The same pool. But now you need to find out how much water will have to be poured into this pool. You need to calculate the volume. (Volumes and liquids, by the way, are measured in cubic meters. Unexpected, right?) Draw a pool: the bottom is a meter in size and a meter deep, and try to count how many cubes measuring a meter by a meter will fit into your pool.
Just point your finger and count! One, two, three, four...twenty-two, twenty-three...How many did you get? Not lost? Is it difficult to count with your finger? So that! Take an example from mathematicians. They are lazy, so they noticed that in order to calculate the volume of the pool, you need to multiply its length, width and height by each other. In our case, the volume of the pool will be equal to cubes... Easier, right?
Now imagine how lazy and cunning mathematicians are if they simplified this too. We reduced everything to one action. They noticed that the length, width and height are equal and that the same number is multiplied by itself... What does this mean? This means you can take advantage of the degree. So, what you once counted with your finger, they do in one action: three cubed is equal. It is written like this: .
All that remains is remember the table of degrees. Unless, of course, you are as lazy and cunning as mathematicians. If you like to work hard and make mistakes, you can continue to count with your finger.
Well, to finally convince you that degrees were invented by quitters and cunning people to solve their life problems, and not to create problems for you, here are a couple more examples from life.
Real life example #4
You have a million rubles. At the beginning of each year, for every million you make, you make another million. That is, every million you have doubles at the beginning of each year. How much money will you have in years? If you are sitting now and “counting with your finger,” it means you are very hardworking man and.. stupid. But most likely you will give an answer in a couple of seconds, because you are smart! So, in the first year - two multiplied by two... in the second year - what happened, by two more, in the third year... Stop! You noticed that the number is multiplied by itself times. So two to the fifth power is a million! Now imagine that you have a competition and the one who can count the fastest will get these millions... It’s worth remembering the powers of numbers, don’t you think?
Real life example #5
You have a million. At the beginning of each year, for every million you make, you earn two more. Great isn't it? Every million is tripled. How much money will you have in a year? Let's count. The first year - multiply by, then the result by another... It’s already boring, because you already understood everything: three is multiplied by itself times. So to the fourth power it is equal to a million. You just have to remember that three to the fourth power is or.
Now you know that by raising a number to a power you will make your life a lot easier. Let's take a further look at what you can do with degrees and what you need to know about them.
Terms and concepts... so as not to get confused
So, first, let's define the concepts. What do you think, what is an exponent? It's very simple - it's the number that is "at the top" of the power of the number. Not scientific, but clear and easy to remember...
Well, at the same time, what such a degree basis? Even simpler - this is the number that is located below, at the base.
Here's a drawing for good measure.
Well in general view, in order to generalize and better remember... A degree with a base “ ” and an exponent “ ” is read as “to the degree” and is written as follows:
Power of a number with natural exponent
You probably already guessed: because the exponent is natural number. Yes, but what is it natural number? Elementary! Natural numbers are those numbers that are used in counting when listing objects: one, two, three... When we count objects, we do not say: “minus five,” “minus six,” “minus seven.” We also do not say: “one third”, or “zero point five”. These are not natural numbers. What numbers do you think these are?
Numbers like “minus five”, “minus six”, “minus seven” refer to whole numbers. In general, integers include all natural numbers, numbers opposite to natural numbers (that is, taken with a minus sign), and number. Zero is easy to understand - it is when there is nothing. What do negative (“minus”) numbers mean? But they were invented primarily to indicate debts: if you have a balance on your phone in rubles, this means that you owe the operator rubles.
All fractions are rational numbers. How did they arise, do you think? Very simple. Several thousand years ago, our ancestors discovered that they lacked natural numbers to measure length, weight, area, etc. And they came up with rational numbers... Interesting, isn't it?
Is there some more irrational numbers. What are these numbers? In short, endless decimal. For example, if you divide the circumference of a circle by its diameter, you get an irrational number.
Summary:
Let us define the concept of a degree whose exponent is a natural number (i.e., integer and positive).
- Any number to the first power is equal to itself:
- To square a number means to multiply it by itself:
- To cube a number means to multiply it by itself three times:
Definition. Raising a number to a natural power means multiplying the number by itself times:
.
Properties of degrees
Where did these properties come from? I will show you now.
Let's see: what is it And ?
A-priory:
How many multipliers are there in total?
It’s very simple: we added multipliers to the factors, and the result is multipliers.
But by definition, this is a power of a number with an exponent, that is: , which is what needed to be proven.
Example: Simplify the expression.
Solution:
Example: Simplify the expression.
Solution: It is important to note that in our rule Necessarily there must be the same reasons!
Therefore, we combine the powers with the base, but it remains a separate factor:
only for the product of powers!
Under no circumstances can you write that.
2. that's it th power of a number
Just as with the previous property, let us turn to the definition of degree:
It turns out that the expression is multiplied by itself times, that is, according to the definition, this is the th power of the number:
In essence, this can be called “taking the indicator out of brackets.” But you can never do this in total:
Let's remember the abbreviated multiplication formulas: how many times did we want to write?
But this is not true, after all.
Power with negative base
Up to this point, we have only discussed what the exponent should be.
But what should be the basis?
In powers of natural indicator the basis may be any number. Indeed, we can multiply any numbers by each other, be they positive, negative, or even.
Let's think about which signs ("" or "") will have powers of positive and negative numbers?
For example, is the number positive or negative? A? ? With the first one, everything is clear: no matter how many positive numbers we multiply by each other, the result will be positive.
But the negative ones are a little more interesting. We remember the simple rule from 6th grade: “minus for minus gives a plus.” That is, or. But if we multiply by, it works.
Determine for yourself what sign the following expressions will have:
| 1) | 2) | 3) |
| 4) | 5) | 6) |
Did you manage?
Here are the answers: In the first four examples, I hope everything is clear? We simply look at the base and exponent and apply the appropriate rule.
1) ; 2) ; 3) ; 4) ; 5) ; 6) .
In example 5) everything is also not as scary as it seems: after all, it doesn’t matter what the base is equal to - the degree is even, which means the result will always be positive.
Well, except when the base is zero. The base is not equal, is it? Obviously not, since (because).
Example 6) is no longer so simple!
6 examples to practice
Analysis of the solution 6 examples
If we ignore the eighth power, what do we see here? Let's remember the 7th grade program. So, do you remember? This is the formula for abbreviated multiplication, namely the difference of squares! We get:
Let's look carefully at the denominator. It looks a lot like one of the numerator factors, but what's wrong? The order of the terms is wrong. If they were reversed, the rule could apply.
But how to do that? It turns out that it’s very easy: the even degree of the denominator helps us here.
Magically the terms changed places. This “phenomenon” applies to any expression to an even degree: we can easily change the signs in parentheses.
But it's important to remember: all signs change at the same time!
Let's go back to the example:
And again the formula:
Whole we call the natural numbers, their opposites (that is, taken with the " " sign) and the number.
positive integer, and it is no different from natural, then everything looks exactly like in the previous section.
Now let's look at new cases. Let's start with an indicator equal to.
Any number to the zero power is equal to one:
As always, let us ask ourselves: why is this so?
Let's consider some degree with a base. Take, for example, and multiply by:
So, we multiplied the number by, and we got the same thing as it was - . What number should you multiply by so that nothing changes? That's right, on. Means.
We can do the same with an arbitrary number:
Let's repeat the rule:
Any number to the zero power is equal to one.
But there are exceptions to many rules. And here it is also there - this is a number (as a base).
On the one hand, it must be equal to any degree - no matter how much you multiply zero by itself, you will still get zero, this is clear. But on the other hand, like any number to the zero power, it must be equal. So how much of this is true? The mathematicians decided not to get involved and refused to raise zero to the zero power. That is, now we cannot not only divide by zero, but also raise it to the zero power.
Let's move on. In addition to natural numbers and numbers, integers also include negative numbers. To understand what a negative power is, let’s do as last time: multiply some normal number by the same number to a negative power:
From here it’s easy to express what you’re looking for:
Now let’s extend the resulting rule to an arbitrary degree:
So, let's formulate a rule:
A number with a negative power is the reciprocal of the same number with a positive power. But at the same time The base cannot be null:(because you can’t divide by).
Let's summarize:
I. The expression is not defined in the case. If, then.
II. Any number to the zero power is equal to one: .
III. A number not equal to zero to a negative power is the inverse of the same number to a positive power: .
Tasks for independent solution:
Well, as usual, examples for independent solutions:
Analysis of problems for independent solution:
I know, I know, the numbers are scary, but on the Unified State Exam you have to be prepared for anything! Solve these examples or analyze their solutions if you couldn’t solve them and you will learn to cope with them easily in the exam!
Let's continue to expand the range of numbers “suitable” as an exponent.
Now let's consider rational numbers. What numbers are called rational?
Answer: everything that can be represented as a fraction, where and are integers, and.
To understand what it is "fractional degree", consider the fraction:
Let's raise both sides of the equation to a power:
Now let's remember the rule about "degree to degree":
What number must be raised to a power to get?
This formulation is the definition of the root of the th degree.
Let me remind you: the root of the th power of a number () is a number that, when raised to a power, is equal to.
That is, the root of the th power is the inverse operation of raising to a power: .
It turns out that. Obviously, this special case can be expanded: .
Now we add the numerator: what is it? The answer is easy to obtain using the power-to-power rule:
But can the base be any number? After all, the root cannot be extracted from all numbers.
None!
Let us remember the rule: any number raised to an even power is a positive number. That is, it is impossible to extract even roots from negative numbers!
This means that such numbers cannot be raised to a fractional power with an even denominator, that is, the expression does not make sense.
What about the expression?
But here a problem arises.
The number can be represented in the form of other, reducible fractions, for example, or.
And it turns out that it exists, but does not exist, but these are just two different records of the same number.
Or another example: once, then you can write it down. But if we write down the indicator differently, we will again get into trouble: (that is, we got a completely different result!).
To avoid such paradoxes, we consider only positive base exponent with fractional exponent.
So if:
- - natural number;
- - integer;
Examples:
Rational exponents are very useful for transforming expressions with roots, for example:
5 examples to practice
Analysis of 5 examples for training
Well, now comes the hardest part. Now we'll figure it out degree with irrational exponent.
All the rules and properties of degrees here are exactly the same as for a degree with a rational exponent, with the exception
After all, by definition, irrational numbers are numbers that cannot be represented as a fraction, where and are integers (that is, irrational numbers are all real numbers except rational ones).
When studying degrees with natural, integer and rational exponents, each time we created a certain “image”, “analogy”, or description in more familiar terms.
For example, a degree with a natural exponent is a number multiplied by itself several times;
...number to the zeroth power- this is, as it were, a number multiplied by itself once, that is, they have not yet begun to multiply it, which means that the number itself has not even appeared yet - therefore the result is only a certain “blank number”, namely a number;
...degree with integer negative indicator - it’s as if some “reverse process” had occurred, that is, the number was not multiplied by itself, but divided.
By the way, in science a degree with a complex indicator is often used, that is, an indicator is not even real number.
But at school we don’t think about such difficulties; you will have the opportunity to comprehend these new concepts at the institute.
WHERE WE ARE SURE YOU WILL GO! (if you learn to solve such examples :))
For example:
Decide for yourself:
Analysis of solutions:
1. Let's start with the usual rule for raising a power to a power:
Now look at the indicator. Doesn't he remind you of anything? Let us recall the formula for abbreviated multiplication of difference of squares:
In this case,
It turns out that:
Answer: .
2. We reduce fractions in exponents to the same form: either both decimals or both ordinary ones. We get, for example:
Answer: 16
3. Nothing special, we use the usual properties of degrees:
ADVANCED LEVEL
Determination of degree
A degree is an expression of the form: , where:
- — degree base;
- - exponent.
Degree with natural indicator (n = 1, 2, 3,...)
Raising a number to the natural power n means multiplying the number by itself times:
Degree with an integer exponent (0, ±1, ±2,...)
If the exponent is positive integer number:
Construction to the zero degree:
The expression is indefinite, because, on the one hand, to any degree is this, and on the other hand, any number to the th degree is this.
If the exponent is negative integer number:
(because you can’t divide by).
Once again about zeros: the expression is not defined in the case. If, then.
Examples:
Power with rational exponent
- - natural number;
- - integer;
Examples:
Properties of degrees
To make it easier to solve problems, let’s try to understand: where did these properties come from? Let's prove them.
Let's see: what is and?
A-priory:
So, on the right side of this expression we get the following product:
But by definition it is a power of a number with an exponent, that is:
Q.E.D.
Example : Simplify the expression.
Solution : .
Example : Simplify the expression.
Solution : It is important to note that in our rule Necessarily there must be the same reasons. Therefore, we combine the powers with the base, but it remains a separate factor:
Another important note: this rule is - only for product of powers!
Under no circumstances can you write that.
Just as with the previous property, let us turn to the definition of degree:
Let's regroup this work like this:
It turns out that the expression is multiplied by itself times, that is, according to the definition, this is the th power of the number:
In essence, this can be called “taking the indicator out of brackets.” But you can never do this in total: !
Let's remember the abbreviated multiplication formulas: how many times did we want to write? But this is not true, after all.
Power with a negative base.
Up to this point we have only discussed what it should be like index degrees. But what should be the basis? In powers of natural indicator the basis may be any number .
Indeed, we can multiply any numbers by each other, be they positive, negative, or even. Let's think about which signs ("" or "") will have powers of positive and negative numbers?
For example, is the number positive or negative? A? ?
With the first one, everything is clear: no matter how many positive numbers we multiply by each other, the result will be positive.
But the negative ones are a little more interesting. We remember the simple rule from 6th grade: “minus for minus gives a plus.” That is, or. But if we multiply by (), we get - .
And so on ad infinitum: with each subsequent multiplication the sign will change. We can formulate the following simple rules:
- even degree, - number positive.
- A negative number, built in odd degree, - number negative.
- Positive number to any degree is a positive number.
- Zero to any power is equal to zero.
Determine for yourself what sign the following expressions will have:
| 1. | 2. | 3. |
| 4. | 5. | 6. |
Did you manage? Here are the answers:
1) ; 2) ; 3) ; 4) ; 5) ; 6) .
In the first four examples, I hope everything is clear? We simply look at the base and exponent and apply the appropriate rule.
In example 5) everything is also not as scary as it seems: after all, it doesn’t matter what the base is equal to - the degree is even, which means the result will always be positive. Well, except when the base is zero. The base is not equal, is it? Obviously not, since (because).
Example 6) is no longer so simple. Here you need to find out which is less: or? If we remember that, it becomes clear that, which means the base is less than zero. That is, we apply rule 2: the result will be negative.
And again we use the definition of degree:
Everything is as usual - we write down the definition of degrees and divide them by each other, divide them into pairs and get:
Before we look at the last rule, let's solve a few examples.
Calculate the expressions:
Solutions :
If we ignore the eighth power, what do we see here? Let's remember the 7th grade program. So, do you remember? This is the formula for abbreviated multiplication, namely the difference of squares!
We get:
Let's look carefully at the denominator. It looks a lot like one of the numerator factors, but what's wrong? The order of the terms is wrong. If they were reversed, rule 3 could apply. But how? It turns out that it’s very easy: the even degree of the denominator helps us here.
If you multiply it by, nothing changes, right? But now it turns out like this:
Magically the terms changed places. This “phenomenon” applies to any expression to an even degree: we can easily change the signs in parentheses. But it's important to remember: All signs change at the same time! You can’t replace it with by changing only one disadvantage we don’t like!
Let's go back to the example:
And again the formula:
So now the last rule:
How will we prove it? Of course, as usual: let’s expand on the concept of degree and simplify it:
Well, now let's open the brackets. How many letters are there in total? times by multipliers - what does this remind you of? This is nothing more than a definition of an operation multiplication: There were only multipliers there. That is, this, by definition, is a power of a number with an exponent:
Example:
Degree with irrational exponent
In addition to information about degrees for the average level, we will analyze the degree with an irrational exponent. All the rules and properties of degrees here are exactly the same as for a degree with a rational exponent, with the exception - after all, by definition, irrational numbers are numbers that cannot be represented as a fraction, where and are integers (that is, irrational numbers are all real numbers except rational numbers).
When studying degrees with natural, integer and rational exponents, each time we created a certain “image”, “analogy”, or description in more familiar terms. For example, a degree with a natural exponent is a number multiplied by itself several times; a number to the zero power is, as it were, a number multiplied by itself once, that is, they have not yet begun to multiply it, which means that the number itself has not even appeared yet - therefore the result is only a certain “blank number”, namely a number; a degree with an integer negative exponent - it’s as if some “reverse process” had occurred, that is, the number was not multiplied by itself, but divided.
It is extremely difficult to imagine a degree with an irrational exponent (just as it is difficult to imagine a 4-dimensional space). It is rather a purely mathematical object that mathematicians created to extend the concept of degree to the entire space of numbers.
By the way, in science a degree with a complex exponent is often used, that is, the exponent is not even a real number. But at school we don’t think about such difficulties; you will have the opportunity to comprehend these new concepts at the institute.
So what do we do if we see an irrational exponent? We are trying our best to get rid of it! :)
For example:
Decide for yourself:
| 1) | 2) | 3) |
Answers:
- Let's remember the difference of squares formula. Answer: .
- We reduce the fractions to the same form: either both decimals or both ordinary ones. We get, for example: .
- Nothing special, we use the usual properties of degrees:
SUMMARY OF THE SECTION AND BASIC FORMULAS
Degree called an expression of the form: , where:
Degree with an integer exponent
a degree whose exponent is a natural number (i.e., integer and positive).
Power with rational exponent
degree, the exponent of which is negative and fractional numbers.
Degree with irrational exponent
a degree whose exponent is an infinite decimal fraction or root.
Properties of degrees
Features of degrees.
- Negative number raised to even degree, - number positive.
- Negative number raised to odd degree, - number negative.
- A positive number to any degree is a positive number.
- Zero is equal to any power.
- Any number to the zero power is equal.
NOW YOU HAVE THE WORD...
How do you like the article? Write below in the comments whether you liked it or not.
Tell us about your experience using degree properties.
Perhaps you have questions. Or suggestions.
Write in the comments.
And good luck on your exams!
The concept of degree in mathematics is introduced in the 7th grade in algebra class. And subsequently, throughout the entire course of studying mathematics, this concept is actively used in its various forms. Degrees are a rather difficult topic, requiring memorization of values and the ability to count correctly and quickly. For faster and quality work with degrees, mathematicians came up with properties of degrees. They help to reduce large calculations, convert a huge example into a single number to some extent. There are not so many properties, and all of them are easy to remember and apply in practice. Therefore, the article discusses the basic properties of the degree, as well as where they are applied.
Properties of degree
We will look at 12 properties of degrees, including properties of degrees with the same bases, and give an example for each property. Each of these properties will help you solve problems with degrees faster, and will also save you from numerous computational errors.
1st property.
Many people very often forget about this property and make mistakes, representing a number to the zero power as zero.
2nd property.
3rd property.
It must be remembered that this property can only be used when multiplying numbers; it does not work with a sum! And we must not forget that this and the following properties apply only to powers with the same bases.
4th property.
If the denominator has a number raised to negative degree, then when subtracting, the degree of the denominator is taken into brackets for the correct change of sign in further calculations.
The property only works when dividing, it does not apply when subtracting!
5th property.
6th property.
This property can also be applied to reverse side. A unit divided by a number to some extent is that number to the minus power.
7th property.
This property cannot be applied to sum and difference! Raising a sum or difference to a power uses abbreviated multiplication formulas rather than power properties.
8th property.
9th property.
This property works for any fractional power with a numerator equal to one, the formula will be the same, only the power of the root will change depending on the denominator of the power.
This property is also often used in reverse order. The root of any power of a number can be represented as this number to the power of one divided by the power of the root. This property is very useful in cases where the root of a number cannot be extracted.
10th property.
This property works not only with square root and second degree. If the degree of the root and the degree to which this root is raised coincide, then the answer will be a radical expression.
11th property.
You need to be able to see this property in time when solving it in order to save yourself from huge calculations.
12th property.
Each of these properties will come across you more than once in tasks; it can be given in its pure form, or it may require some transformations and the use of other formulas. Therefore for the right decision It’s not enough to know just the properties; you need to practice and incorporate other mathematical knowledge.
Application of degrees and their properties
They are actively used in algebra and geometry. Degrees in mathematics have a separate, important place. With their help, exponential equations and inequalities are solved, and equations and examples related to other branches of mathematics are often complicated by powers. Powers help to avoid large and lengthy calculations; powers are easier to abbreviate and calculate. But for working with large degrees, or with degrees large numbers, you need to know not only the properties of degrees, but also work competently with bases, be able to decompose them in order to make your task easier. For convenience, you should also know the meaning of numbers raised to a power. This will reduce your time when solving, eliminating the need for lengthy calculations.
The concept of degree plays a special role in logarithms. Since the logarithm, in essence, is a power of a number.
Abbreviated multiplication formulas are another example of the use of powers. The properties of degrees cannot be used in them; they are expanded according to special rules, but in each formula of abbreviated multiplication there are invariably degrees.
Degrees are also actively used in physics and computer science. All conversions to the SI system are made using powers, and in the future, when solving problems, the properties of the power are used. In computer science, powers of two are actively used for the convenience of counting and simplifying the perception of numbers. Further calculations for converting units of measurement or calculations of problems, just like in physics, occur using the properties of degrees.
Degrees are also very useful in astronomy, where you rarely see the use of the properties of a degree, but the degrees themselves are actively used to shorten the notation of various quantities and distances.
Degrees are also used in everyday life, when calculating areas, volumes, and distances.
Degrees are used to record very large and very small quantities in any field of science.
Exponential equations and inequalities
Properties of degrees occupy a special place precisely in exponential equations and inequalities. These tasks are very common, as in school course, and in exams. All of them are solved by applying the properties of degree. The unknown is always found in the degree itself, so knowing all the properties, solving such an equation or inequality is not difficult.
